Water distribution apparatus



May 11, 1943. R. REYNOLDS WATER DISTRIBUTION APPARATUS 6 Sheets-Sheet 1 Filed Oct. 25, 1938 y 1943- R. REYNOLDS WATER DISTRIBUTION APPARATUS Filed 001;. 25, 1938 6 Sheets-Sheet 2 R. REYNOLDS WATER DISTRIBUTION APPARATps Filed Oct. 25, 1938 May 11, 1943.

6 Sheets-Sheet 3 Relay Circuit Controls AW May 11, 1943.

R. REYNOLDS 2,318,969

WATER DISTRIBUTION APPARATUS Minuet Control May 11, 1943. R. REYNOLDS 2,313,969

WATER DISTRIBUTION APPARATUS Filed Oct. 25, 1938 a Sheets-Sheet 5 Hour ('oV/Tro/ Electric C'loc/f Master SWL tcfi May 11, 1943. R. REYNOLDS WATER DISTRIBUTION APPARATUS Filed Oct. 25, 1938 6 Sheets-Sheet 6 Patented May 11, 1943 UNITED STATES PATENT OFFICE WATER DISTRIBUTION APPARATUS Richard Reynolds, Washington, I 0. Application October 25, 1938, Serial No. 236,961

6 Claims.

This invention is a. water distribution-apparatus designed primarily for sprinkling lawns of large areas, although not limited to this particular use.

One of the objects of the invention is to provide a water-distribution apparatus for automatically turning water on and off at predetermined intervals of time. A further object is to provide an apparatus so designed that the water may be alternately turned on and off at predetermined intervals during any period of the day forth and particularly pointed out in the claims.

In the accompanying drawings:

Figure 1 is a front elevation illustrating the apparatus in a more or less diagrammatic manner. Figure 2 is a side elevation of the control board. Figure 3 is a side elevation illustrating the valve-control mechanism. Figure 4 is a vertical sectional view on the line ,fl-B, Figure 3.

Figures 5 and 6 are detail sectional views illustrating one of the valve-operating members. Figures 7, 8 and 9 are diagrammatic views of the wiring of the control system, which views must be considered with relation to each other, Figure 7 being a diagrammatic view illustrating the motor-operating circuits and the relay circuits controlling the latter; Figures 8 and 9 being diagrammatic views illustrating the time-control circuits. Figure 10 is a detail plan view of the movable contact arm for the minute control circuits of Figure 8. Figure 11 is a detail view of the time-changing disk for selectively limiting opperation of the apparatus to predetermined a. m. and p. m. periods, respectively. Figure 12 is a detail sectional view illustrating the mounting of the hour and minute shafts of the clock mechanism. Figure 13 is an explanatory dia of the wiring of Figures '7, 8 and 9, parts gram I purpose of simplification being omitted for the in tracing the circuits.

Referring to Figure 3 of the drawings, A designates a frame which is provided with a plurality of upright members a, a, a a, and a, which serve to-support two fixedly mounted shafts C and C, respectively in axial alignment.. Sleeves C and C are rotatively mounted on said respective shafts, and are respectively provided with cams D and D mounted to rotate therewith. Rotation is imparted .to sleeve C by means of a motor F, the shaft of which carries a beveled gear I meshing with a complemental gear 1 connected with a worm shaft .1 The latter drives a worm gear I mounted on and rotatable with said sleeve C Rotative movement is imparted to sleeve 0* by a second motor F, through the medium of similar beveled and worm gearand connected to the stem Z of a supply valve D which controls the water supply to a distribution chamber D through pipe (1 Said chamber is supported in frame A by the rod a and bolts d The valve D is normally held in closed po sition by a spring Z positioned to react against an abutment Z During rotation of the cam D, the cam surface (2 will engage the arm 6. in such manner as to unseat valve D against the ten sion of its spring Z, and will retain it in that position until the cam is moved to release said arm.

Cam D is provided with a cam surface :1 so positioned as to successively engage a plurality of actuator arms (i one for each of a plurality of valves D separately controlling flow of water from chamber D through a corresponding number of discharge pipes d". The valves D are normally seated by means of springs d and there is one unseating arm (1 for each valve D The arms d and d are identical in structure, arrangement, and operation, and are illustrated in detail in Figures 4, 5 and 6. As shown, each arm is pivoted at P to a part a of the frame A, and is provided with a slotted opening P through which a valve stem-such as valve stem cl for instance-15 extended. The valve stem and the arm are pivotally connected at P By means of this arrangement, the valve spring will always tend to maintain the arm in position to be engaged by its operating cam. The valve stem is guided by means of a sleeve P and its outward movement is limited by a stop P The stem of each of the valves 13 is connected with a spring (i and each arm (2 is mounted and operated in identically the same manner as illustrated in Figures and 6, and already described with respect to the arm d.

The circuits to the motors F and F are automatically controlled by a System of relays in association with contacts carried by the sleeves C and C. For instance, the sleeve C is provided with a contact E in the form of a concentric ring, and with two other concentric contacts E and E see Figure 7. In a similar manner the sleeve C is provided with a ring-like contact E and two concentric segmental contacts E and E. Contacts E and E are connected by a wire E contacts E and E are connected by a wire E, and contacts E and E are connected by a wire E. The contact ring E is at all times engaged by a fixed contact E and a similar contact E is positioned to engage segment E; A plurality of circumferentially spaced fixed contacts E, E E E E and E are positioned to engage the segment E. A fixed contact E is in constant engagement with contact ring E, a plurality of circumferentially spaced fixed contacts E, E, E and E are positioned to engag segment E and a. plurality of fixed circumferentially spaced contacts E and E are arranged to engage the .segment E Contacts E and E are'connected -bya-wire- I25 .and contacts E and E are connected by a wire I21. A wire I24 is provided with branchesconnecting contact E with contacts 17 E18 and E19.

The circuit to the motor F is automatically controlled by relays R, R, and the circuit to metor F is controlled by relays R and R Referring more particularly to Figure 7 of the -drawings, I0, I I designate typical line wires of the usual 110 volt street current. Connected with wire iii are two wires l3 and I5, respectively, and connected with wire II are two wires Iii and I5 respectively. The wires I3 and i3- provide the primary circuit for a transformer T of any suit able structure, wound to reduce the 110 volt current to two selective lower voltage secondary circuits, one for approximately 14 volts and including the wires l4 and I4, and the other for 6 volts and including wires H and I4. In the wiring diagrams the 110 volt circuits are indicated by heavy lines, the 6 volt and 14 volt circuits are indicated by light lines. The wire I5 is connected by a wire l5 with a wire l5 which in turn is provided with a plurality of branch wires l5, l5", |5, i5 and I5 respectively connected with the movable contacts 1', r, 1 r and r of the relays R, R', RR, R and R The fixed contacts is and I! of relays R and R are connected with a wire II, which in turn is connected to one terminal of the motor F. The other terminal of the said motor is connected by wires i3 and l3 with the wire B The fixed contact r of relay R is connected by wire 21!* with the wire il The fixed contacts r and r of relays R and R are connected with one terminal of motor F by means of wire 20, a wire i3 leading from the other contact of said motor to the above mentioned wire i3.

Connected with one terminal of the coil of relay R is a wire 22, the other terminal thereof end of the coil of relay R is a wire 22 and the other end thereof is connected with contact E" by a wire 2l. One end of the coil of relay R is connected with wire II by means of a wire ll and the other end thereof is connected with contact E" by wire li From the foregoing it will be readily understood that relays R and R control the circuit of motor F and that relays R and R control the circuit of motor F. The functions of th relay R will b later described.

A system for automatically controlling the operation of the relays is illustrated in Figures 7, 8 and 9. Referring more particularly to the last mentioned figures in conjunction with Figures 2, 11 and 12, an electrical clock EC of any preferred construction is mounted upon a panel board S. Said clock is provided with the usual train of gears operating the hour. minute and second shafts carrying suitable indicating hands. The clock motor circuit includes'trunk wire Ifl, wire I5, the clock motor CM, wire I5 and trunk wire II. The hour shaft 3i is broken as indicated at 32, the minute and second shafts 3i and 3 l respectively, being extended therethrough in the usual manner. Mounted upon the rear section of the hour shaft 3| is a pulley 33, which is connected by a belt 34 with a complemental pulley 33* on counter shaft 36. The latter is provided with a second pulley 31 connected by a belt 38 with a pulley 31", carried by an extension 40 of the hour shaft 3 i.

Supported by panel board S is a circuit controlling device TC for energizing motor F at in tervals of less than one hour, the same comprising a base provided with three concentric conthe largest ring 43 are a plurality of series of concentrically disposed fixed contacts 50, 5i and 52 respectively, there being twelve contacts in each series, so arranged that they are disposed in radial sets, each set containing one each of contacts 50, 5| and 52, the radial sets being located at positions corresponding to those of the numbers on a clock face, see Figure 8.

Secured to and rotatable with the minute shaft 32 of the clock is a distributor bar 44 of sufllcient lengthto extend radially across the face of the control device TO to a position beyond ring 43. Said bar 44 is provided with a contact 45 which is at all times in engagement with the ring I, a second contact 46 at all times successive sets of contacts 52, 50 and 5|, respeccontact E by a wire 2i Connected with one tively, during rotative clockwise travel of said bar. Contact 53 is connected with contact 41 by a wire 56, contacts 54 and 46 are connected by a wire 51, and contacts 55 and I5 are connected by a wire 58. H designates an "hour" control switch, consisting of a base provided with a central contact ring 53 arranged concentrically with respect to the axis of the hour shaft, and with a plurality of contacts 64 surrounding said ring and occupying positions corresponding to the number-positions on a clock face. Ring 63 is connected by a wire 60" with one fixed contact Ms. switch II, the movable member of the latter being connected with a wire 10. The other fixed contact of said switch II is connected with ring 43 of the control TO by a wire 12. Secured to and rotatable with the hour shaft 32 is a dis- 7 hour control TC by means of a wire X there being twelve of such wires.

The conductors X are also connected by branch wires X with a corresponding number of juxtapositioned sets of contacts carried by a movable arm M of a master switch MS. There are two sets of said contacts m, m, and six in a set. the contacts m being connected to those wires X which are in circuit with contacts 52 at the clock-face positions numbered from 2 to I2, both inclusive, and the contacts m being connected with those wires X which are in circuit with contacts 52 at odd hour the clock-face positions, as indicated by the numbers. Associated with the series of contacts m but isolated therefrom is a contact m connected with wire 22, and associated with the group of contacts m but isolated therefrom is a contact 111. connected with wire 22.

The switch arm M is centrally pivoted with respect to a ring M and disposed within said ring are four groups of contacts MS, MS, MS

and MSHrespectively, all arranged to be selectively covered by the contacts of arm M in a manner to bring the latter into register with contacts of each selected roup. The group MS contains exactly the same number of contacts as are shown on the arm M and predeterminedly positioned with respect to the contacts m and m and their relation to clock-face-number positions, as well as contacts m and m oomplemental to contacts m and m The contacts numbered 8, 3, 5, I, 9, II and m of group MS are connected in series by suitable conductors, and the contacts m numbered 2, A, 5, 8, I and I2 of group MS are similarly connected in series with the contact m When the arm M has been adjusted to engage the contacts of group MS, all of the contacts m and m will be in register with correspondingly numbered contacts of said group MS. Also the contact m of said last mentioned group will be engaged with contact 'm. of the switch arm, and the contact m will be engaged with the contact m of the switch arm. This arrangement assures operation of the apparatus at 5 minute intervals.

The group of contacts M8 is intended to operate the device at minute intervals, but it will be observed that said group is limited to a duplication of the even-hour-positioned contacts of group MS, i. e. those complemental to contacts m and contacts m plus contact m. The contacts of group MS which correspond to clockface numbers 4, 8 and I2 are connected in multiple with the contact m and the contacts -corresponding to clock-face numbers 2, 6

and I Il are connected in multiple with the contact m The third group of contacts MS is intended to control the apparatus at minute intervals. This group consists of four contacts respectively corresponding to clock-face numbers 3, 6, 9, I2, and to contacts m and m The contacts 6 and I2 are connected in multiple with contact m and the contacts 3 and 9 are connected in multiple with the contact m.

The set of contacts M8 is designed for half hourly operation and involves only four contacts, namely those corresponding to the 6 and 12 o'clock positions of the clock face, and contacts m" and m Contact for six o'clock position is in circuit with contact m and the contact for 12 o'clock position is in circuit with the contact m, y

When the apparatus is initially installed the sleeve C must be placed in the full-line position of Figure 7 and with the cam surface d in the full-line position of Figure 3. At this time valve D will be closed. To manually start operation of the apparatus, switch 85 is adjusted to connect wires 84 and 89, and switch I3 is adjusted to connect wires 89 and 22. These adjustments will establish a relay circuit including transformer T, wires I4 and 0, contact 0 and 0', wires 0 and 84, switch 85, wire 89, switch I3, wire 22, relay R wire 2 l contact E wire E" contact E wire I21, and wire I4 to the transformer (see Figure 13). Energization of .relay R closes the circuit to the motor F so as to efiect rotation of the sleeve C until the contact E moves out of engagement with the brush E, at which time the motor circuit is broken, and the contact E is engaged with the brush E At the same time contact E will have been disengaged from the brushes E and E and moved into engagement with brushes E and E In order to arbitrarily close the valve D and thereby arrest the flow of water to the drum D the switch I3 will be adjusted to close the circuit through wire 22 to relay R The circuit thus established includes the transformer T, wires I4 and 0 movable contact O and 0'', wires 0 and 84, switch 85, wire 89, switch I3, wire 22', relay R wire 2", contact E contact E wire E contact E wire I2! and wire It to transformer T. This will eifect the energization of the motor F" and cause the carrier C to rotate 180 or until the contact E moves to the full-line position, out of engagement with the brush E, If the rain control 0 is not employedthe wire I4 will be directly connected to wire 84 and except for this the circuits established are the same as above described. Of course,

if the rain control has automatically operated to break the circuit between contacts 0 and O, the relay circuits will be correspondingly broken.

It is also essential that the contact E be init ally in the full line position of Figure 7, and if operation of the apparatus is interrupted for any reason, and the said contact is not in its said full line position, a circuit will be automatically closed through the relay R to energize the motor F and effect rotation of the carrier 0 until the contacts E and E are brought to their full line positions. Said circuit includes wires I4 and I4, relay coil R wire 2I contact E wire I26, contact E wire E contact E, wire I21 and wire I4 to the transformer T. This will close an energizing circuit for the motor F, which circuit has already been fully described and will effect rotation of the carrier C until the contacts E and E are brought to the full line positions. The last I mentioned circuit will also be automatically established by the above mentioned adjustment of contact E to close valve D because the con- -tact E will thereby be brought to the full-line position of Figure 7.

Duringthese operations the switches I00 and I02 must be in neutral positions. Automatic starting and stopping of the control apparatus is eiiected by the switches B and B operating in conjunction with a clock-operated switch. as shown in Figure 8. The switches B and B respectively comprise contact rings 00, each surrounded by twelve concentrically arranged contact points 8|, BI, respectively. Mounted upon centrally disposed pivots are manually adjustable contact bars 82, 82', provided with con- X' with contacts of the said minute control in asimilar manner. The ring 80 is connected by wire I03 with the movable contact of a two-way switch I02 and the ring 80 is connected by wire IOI to the movable contact of a two-way switch I00. The cars 82 and 82' are normally adjusted to open-circuit positions.

The clock EC is provided with a time control switch comprising a contact plate G, and three fixed contacts G", G and G respectively. The plate G is rotatively driven by the clock gearing and is of such size that while in full line position Figure 9, it will maintain engagement with the contacts G and G for the first twelve hours of a day and while in dotted line position, to maintain engagement with the contacts G and G for the second twelve hours of the day. Contact 6 is connected by a wire G with one fixed terminal or two-way switch 85. The contact G is connected by a wire G with one fixed contact 01' two-way switch I02. Contact G is connected by a wire G with a. fixed contact of two-way switch I00. Said wire G is connected by a branch wire 95 with the other fixed contact of the switch I00, so as to by-pass switch I02. The wire G" is connected by a wire I04 to the other fixed contact of the switch I02, so as to by-pass switch I00.

It is preferred to provide means for automatically cutting oil the water supply in case oi rain, although this means may be omitted without departing from the spirit of the invention. Such a device as illustrated in Figure 7 comprises a float chamber 0, having a supply pipe 0', for delivering drainage water during a rain storm into said chamber. Said supply pipe may be provided with a manual shut oil valve 0 The chamber O is provided with an outlet pipe 0 controlled by a manual valve 0, an overflow pipe 0 being arranged to by-pass said valve 0 Located in a position above the normal high water level within chamber 0 is a control switch having two fixed contacts 0" and 0, and a movable contact 0" is so mounted at 0 as to be moved by an arm connected with a float 0" within said chamber 0. Downward movement of the. float may be limited by an adjustable stop 0. Contact 0" is connected by wire 0 with wires I0 and 84. Wire terminates at the movable member H of the two-way switch 'II', the wire 84 leading to the movable member of the two-way switch 85. The contact 0 is connected with the wire 22 by wire 0 The contact 0 is connected to wire I4 by wire 0".

Transformer wire I4 is connected with one terminal of a lamp I I0, the other terminal of this lamp being connected by wire I09 with one contact of a switch 86, the other contact of said switch being connected with wire I04 by wire I00. Wire I4 is also connected by a wire III with one contact of lamp I I0, the other contact of said lamp being connected to a contact of switch 04 by a wire 96. The other contact of switch 84 is connected by wire I05 with wire-95.

In practice, the operations of the motor F are automatically controlled by relays R and R, and the operations of the motor F are automatically controlled by the relays R and R The circuits through relays R and R are controlled by the contacts E and E of the control apparatus A. and the circuits through the relays R and R are controlled by the contact E The contact E is definitely positioned with respect to the cam d which operates the valves D, i. e. it occupies the same radical position with respect to the axis of sleeve C as is occupied by said cam.

The circuits to the various relays are controlled selectively by the minute control TO, the hour control H, the master switch MS, and the switches B and B, determined by the respective selective settings thereof, and typical circuits are shown in Figure 13.

When it is desired to operate the water controlling valves D at intervals of less than one hour, the arm M is manually adjusted to engage a selected group of contacts of the switch MS, depending upon whether 5 minute, 10 minute, 15 minute, or 30 minute intervals is desired. Assuming that a 5 minute interval is desired, the switch arm M will be adjusted to engage the contacts of group MS and the switch II will be adjusted to place wires I0 and I2 in circuit. The intervals of the operations will be controlled by the clockwise movement of the contact arm 44 around the face of the minute control TC. Each circuit thereby established will include transformer T, wires I4 and 0 contacts 0 and 0 wire 0 and wire 10, switch II, wire I2 to contact ring 43, contact 41, wire 56, contact 53, a se lected contact 52, the wire X? connecting said contact 52 with a complemental contact of switch arm M. If said complemental contact is one of group m the circuit will be completed so as to include contacts m and m, wire 22, relay R, wire 2|, contact E, contact E wire I24, contact E (which at that time will be in one of its circuit closing positions with wire I24) wire E contact E, wires I21, I4 and transformer T. If the above mentioned complemental contact of switch arm M is one of the m group the circuit will be completed so as to include contacts m and m wire 22*, relay R, wire 2| to contact E and then to transformer T through the same course as described for contacts of group m. By means of this arrangement the motor F will be intermittently operated each time contact 53 engages a contact 52, and the contact E will be moved to a new position. Similar intermittent operations of the motor F but at selective longer intervals of time will be eifected by adjustment of arm M to any of the contact groups of switch MS. Operation of the apparatus may be arrestgcli at any time by breaking the circuit at switch sitioned contact 8| and arm 82a is similarly adjusted to bring its contact 85a into engagement with any pre-selected clock-face-positioned contact 8 I. By adjusting switch 85 to close the circuit between wires 84 and G a circuit will then be established to include the transformer T, wires I4 and contacts 0 and 0'', wires 0 and 84, switch 85, wire G and contact G Under these conditions, assuming that the clock-operated contact G is in the full-line or a. m. position of Figures 9 and 13, when the contact arm 44 of control TCreaches the contact 50 occupying the same clock-face-position as the pre-selected contact 8|, the contact G will close a circuit which includes contacts G and G wire G switch I02, wire I03, through switch B to wire X, contacts 50, 54, wire 51, contacts 48 and 42, wire 22, relay R wire 2 I, contacts E and E wire'E contact E wires I21 and I4 to transformer. Thus, the circuit to motor F is closed through relay R and cam member D is operated to open valve D and the timing operations through controls TC, H and M will not be afi'ected. When the arm 44 moves to the position of the contact 5| of control TC, which corresponds to the clock-face-position of the selected contact 8| of switch B, a circuit will be established from the plate G which will include contacts G wire G wire 95, switch I00, wire IOI,

through switch B to wire X, contacts 5| and 55, a

wire 58, contacts and 4|, wire 22", relay R wire 2|, to contact E and from contact E to the transformer as already described. This will energize motor F from relay It to rotate cam member D to valve-closed position.

If it is desired to start the apparatus manually at any time, and to stop it automatically during the morning period, the switch bar 82 is adjusted to engage the contact 8| corresponding to the hour at which it is desired to stop, and switch I02 is adjusted to connect wires G and I03. Switch I00 isalso adjusted to neutral position. The switch 85 is then adjusted to place wires 84 and 89 in circuit, and the circuit to motor F is manually closed by adjusting switch 13 to connect wires 89 and 22. This will open the valve D after which the switch 13 is brought to neutral position. With these adjustments, when the arm 44 reaches the clock-face position corresponding to the clock-face position of the switch arm 82, and the contact G of the clock switch engages the contact G a relay circuit will be established including transformer T, wires I4 and 0 contacts 0 and 0'', wires 0 and 84, switch 85, wire G contacts G and G wire G switch I02, wire I03, switch B to wire X, contacts and 54, wire 51, contacts 46 and 42, relay R?, wire 2I contacts Iii and E wire I21, and wire I4 to the transformer (see Figure 13). This will energize motor F sufficiently to rotate the cam D so as to efiect closing of the valve D and also to break the circuits to the relays R and R. If the apparatus is to be arrested during the afternoon period, switch I02 is moved to a neutral position and switch I00 is adjusted to connect wires G and IN, the switch 85 being adjusted to connect wires 84 and G. Also, the arm 82 of the switch B will be adjusted to engage the contact 8|- which corresponds to the clock-face position representing "the time at which the apparatus is to be stopped.

With the parts so adjusted, the circuit from the transformer T to the clock switch is the same as described for the a. m. adjustment. When the clock switch moves to a position to bring the contacts G and G into engagement and the arm 44 reaches a clock-face position corresponding to that of the arm- 82, the circuit from G will include contact G wire G", switch I00, wire IOI, switch .3, wire X to contacts 5| and 55, wire 58, contacts 45 and 4|, wire 22 to relay R wire 2|", contacts E and E wire E contact E wires I21 and I4, to thetransformer. By this means the motor F is energized to rotate the cam D to closed position and the circuits to relays R and R are broken.

When the valve D has been seated upon cessation of operation of the system for any reason. the contact E will come to rest in the full line position of Figure 7. If at this time contact E is not in the full line position of said Figure '7, relay R will be automatically energized to close the circuit to ,motor F, and to effect rotation of said contact E to the full line position. This relay circuit has already been described.

The advantages of the invention will be readily understood by those skilled in the art to which it belongs. For instance, it will be readily observed that a very simple form of water distribution unit is provided, and means associated therewith for accurately regulating said apparatus in such manner as to insure operation thereof at predetermined and regular intervals of time. Also, that easily operable means is provided for varying the lengths of said operation intervals to suit substantially all practical requirements of normal operating conditions.

Having thus explained the nature of the invention and described an operative manner of constructing and using the same, although without attempting to set forth all of the forms in ,which it may be made, or all of the forms of its use, what is claimed is:

1. A water distribution apparatus comprising a chamber having a plurality of independent outlets controlled by independently movable valves each of which is normally biased to closed position, a supply chamber, a normally seated main valve controlling the supply of water to said chamber, a rotatively mounted cam member for unseating said main valve, a motor for imparting rotative movements to the cam member, a second rotatively mounted cam member having means for successively unseating the outlet valves, a second motor for actuating said second cam member, adjustable time-control means for antomatically connecting said motor with a source of power at variable intermittent pre-selected intervals of time, whereby said cam will successively unseat the outlet valves at intervals of time corresponding to said intermittent periods and means operative while the second motor is idle for automatically and temporarily energizing said second motor, so as to bring said second cam to a predetermined position.

2. Ina water distribution apparatus, a chamber provided with a plurality of outlets controlled by independently movable valves each of which is normally biased to closed position, an electric motor, means actuated by said motor for successively opening said valves, a plurality of relay switches normally controlling the motor circuit, the coil of each relay being included in a separate circuit, a selective switch operated by said motor and having contacts complemental to the respective relay circuits, and a time-controlled switch having contacts cooperating with the contacts of the selective switch to selectively close the respective relay circuits at constantly recurring intermittent intervals, and time-interval-control means for connecting said time-controlled switch with the relay circuits and having means for selectively predetermining the frequency oi the intermittent energizations of said relays.

3. In a water distribution apparatus, a chamber provided with a plurality of outlets controlled having contacts controlling the relay circuits, a

time-controlled switch having means for automatically energizing the relay circuits at hourly intervals, 9. second time-controlled switch for automatically energizing the relay circuits at shorter intervals, means for connecting either switch with a source of electrical energy, and a common means for connecting both switches with the relay circuits.

4. In a water distribution apparatus, a chamber provided with a plurality of outlets controlled by independently movable valves each of which is normally biased to closed position, an electric motor, means actuated by said motor for successively opening said valves, a plurality of relay switches controlling the motor circuit, the coil or each relay being included in a separate circuit, a selective switch operated by said motor and controlling the relay circuits, time-controlled means for intermittently closing the relay circuits at predetermined intervals, means for connecting the last mentioned means with the relay circuits, and emergency means for automatically breaking the circuit to said time-controlled means. 7

5. In a water distribution apparatus, a chamber provided with a plurality of outlets controlled by independently movable outlet valves each of which is normally biased to closed position, a main valve controlling the supply of water to said chamber and normally biased to closed position, v

means for unseating said valve, an electric motor, means actuated by said motor for successively opening said valves, a plurality of relay switches controlling the motor circuit, the coil of each relay being included in a separate circuit, a selective switch operated by said motor and controlling the relay circuits, time-controlled means for intermittently closing the relay circuits at predetermined intervals, means for connecting the last mentioned means with the relay circuits, emergency means for automatically breaking the circuit to said time-controlled means, and means operating in timed relation with said main-valveopening means to temporarily energize said motor independently of said relay circuits, so as to place said selective switch in a predetermined position when said motor has become disabled.

6. A water distributing apparatus comprising a chamber having a plurality of independent outlets controlled by independently movable outlet valves normally biased to seated position, an electric motor, a plurality of relay switches controlling said motor and included in separate circuits, means operated by said motor for successively unseating said valves, 9. main supply valve controlling flow of water to said chamber, said valve being normally biased to seated position, a second electric motor for operating said main valve, additional relay switches controlling said second motor and also included in separate circuits, time control means operable to automatically energize the relays of the first motor at successive predetermined positions, so as to successively unseat the outlet valves at corresponding predetermined intervals, and means connected with the time control means for automatically and selectively energizing the relay circuits of the second motor, so as to open and close the main valve and to simultaneously open and close the circuits to the relays controlling the first motor at predetermined times during the operation of said time control means.

RICHARD REYNOLDS. 

